Modelling of an Integrated Plasma Gasification Combined Cycle power plant using Aspen Plus

Q1 Chemical Engineering

Journal of King Saud University, Engineering Sciences Pub Date : 2024-12-01 DOI:10.1016/j.jksues.2022.06.004

Néstor D. Montiel-Bohórquez, Andrés F. Agudelo, Juan F. Pérez

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Abstract

The development of a steady-state model of an Integrated Plasma Gasification Combined Cycle (IPGCC) power plant is presented here. The model includes the plasma gasifier, syngas conditioning units, and the power generation unit. Furthermore, the model of each component implemented in Aspen Plus is described in detail (thermodynamic method, chemical reactions, and operative conditions). The proposed model was validated by comparing the plasma gasification results with experimental and numerical data from the literature; the relative error was 6.23% and 5.24%, respectively. The model was then used to perform a two-part sensitivity analysis. In the first part, simulations with municipal solid waste (MSW) with a moisture content varying from 20% to 60% were performed. The moisture content increment reduced the torch-specific power consumption by 53%. However, because of the increasing specific fuel consumption, the thermal efficiency of the IPGCC power plant also decreased by 28% as the MSW moisture content increased from 20% to 60%. In the second part, it was determined that the IPGCC power plant reached the best performance (32.5%) when a high plasma temperature (5000 °C) and a low gasification temperature (2000 °C) were used. At these highest efficiency conditions, the 1000 t/day IPGGC power plant’s net power generation was 62 MWe.

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基于Aspen Plus的一体化等离子气化联合循环电厂建模

本文介绍了综合等离子气化联合循环（IPGCC）电厂稳态模型的开发。该模型包括等离子气化炉、合成气调节装置和发电装置。此外，详细描述了在Aspen Plus中实现的每个组件的模型（热力学方法，化学反应和操作条件）。通过将等离子体气化结果与文献中的实验数据和数值数据进行比较，验证了所提模型的正确性；相对误差分别为6.23%和5.24%。然后使用该模型进行两部分敏感性分析。在第一部分中，对含水率从20%到60%不等的城市固体废物（MSW）进行了模拟。含水率的增加使火炬比功耗降低了53%。然而，由于比燃料消耗的增加，IPGCC电厂的热效率也随着MSW含水率从20%增加到60%而下降了28%。在第二部分中，确定了IPGCC电厂在使用高等离子体温度（5000℃）和低气化温度（2000℃）时达到最佳性能（32.5%）。在这些最高效率条件下，1000吨/天的IPGGC发电厂的净发电量为62兆瓦。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of King Saud University, Engineering Sciences Chemical Engineering-Fluid Flow and Transfer Processes

CiteScore

12.10

自引率

0.00%

发文量

审稿时长

63 days

期刊介绍： Journal of King Saud University - Engineering Sciences (JKSUES) is a peer-reviewed journal published quarterly. It is hosted and published by Elsevier B.V. on behalf of King Saud University. JKSUES is devoted to a wide range of sub-fields in the Engineering Sciences and JKSUES welcome articles of interdisciplinary nature.